Offset drive system for utility vehicles

ABSTRACT

A wheel driven utility vehicle includes a frame and two small volume high speed alternating current electric motors arranged side by side for driving the vehicle. Alternatively high speed direct current, hydraulic or pneumatic direct current motors may be used with suitable controls. Each motor has an output shaft which drives an offset planetary gear reducer. Each offset planetary gear reducer is affixed to the electric motor and includes an output carrier interconnected with an output shaft. Each output shaft includes first and second chain drive sprockets which drive chains interconnected with shafts driving the front and rear wheels respectively. Each offset planetary gear reducer enables use of space saving high speed relatively low-torque alternating current electric motors with attendant large speed reductions. Gear reduction enables the production of sufficient torque at the wheels of the vehicle. Applications in addition to utility vehicles are also specifically contemplated.

FIELD OF THE INVENTION

The invention is in the field of offset drive systems for utility vehicles. In particular, this invention is in the field of utility vehicles (such as Skid-Steer(g and Bobcat® vehicles), fork lifts and front end loader machines.

BACKGROUND OF THE INVENTION

Traditionally, Skid-Steer® Loader Machines as made famous by manufacturers such as Bobcat® and the like have been powered almost exclusively by hydraulics. Skid-Steer® is a registered trademark of Arts-way Manufacturing Co., Inc., a Delaware Corporation. Bobcat® is a registered trademark of Clark Equipment Company of New Jersey.

These machines traditionally have gasoline or diesel internal combustion engines that drive a hydraulic pump. The pump usually provides power to two independently controlled hydraulic motors one for each side of the machine. The output of each motor drives a drive sprocket with two sets of sprocket teeth. One set of sprocket teeth drives a chain that goes to a front wheel sprocket and the other set of sprocket teeth drives a chain that goes to the rear wheel sprocket. The hydraulic pump also provides power for lifting functions and power takeoffs for implements that can be connected to the machine.

U.S. Pat. No. 4,705,449 to Christianson et al. discloses the use of two electric traction motors. FIG. 1 is a plan view of an electric drive system of U.S. Pat. No. 4,705,449 to Christianson et al. wherein battery 28 supplies electric power to two traction motors 60, 64 which in turn are coupled 84 to a gear reducer 82. Specifically, the '449 patent states at col. 4 line 10 et seq.: “a first traction motor 60 provides the motive force for the left-hand side of the vehicle and a second traction motor 64 provides the motive force for a right-hand side of the vehicle 66. Both the first traction motor 60 and the second traction motor 64 are powered by a battery pack 28. . . . Similarly, the traction motor 64 is connected to a spur gear reduction assembly 82 through a coupling 84. The spur gear reduction assembly engages a chain 86 which in turn engages a right rearward gear 74 and left forward gear 90, which are respectively connected to wheels 14 a and 14 b through axles 92 and 94. As will be appreciated, the traction motor 60 is operated independently of the traction motor 64 thereby permitting the wheels 14 c, 14 d to operate at different speed than wheels 14 a and 14 b to create skid steering.”

U.S. Pat. No. 4,705,449 to Christianson et al. discloses the use of two electric traction motors. The motors are not identified by type in Christianson et al as either DC or AC. However, the motors are DC electric motors as they are controlled by a device identified in the '449 patent to Christianson, namely, a General Electric EV 1 SCR Controller, which is designed to control DC motors. The General Electric EV 1 SCR Controller describes the use of rectifiers to pulse power to DC motors and has no provision for the control of AC motors.

A copy of the EV 1 SCR Controller technical literature is submitted herewith in an Information Disclosure Statement and describes the use of the controller as being for the control of DC motors. Additionally, the EV 1 SCR Controller is identified in U.S. Pat. No. 4,265,337 to Dammeyer entitled Fork Lift Truck Speed Control Upon Fork Elevation and is used to control a DC motor 92.

Additionally, the EV 1 SCR Controller has been used in numerous automobiles (electric vehicles) in conjunction with DC series wound motors which provide high current and high torque at low rpm.

DC traction motors have been used in applications involving forklifts and similar vehicles in the past. Internal combustion engines are not favored in such applications because an internal combustion engine produces zero torque at zero engine speed (RPM) and reaches its torque peak later in its operating range. Internal combustion engines generally require a variable-ratio transmission between the engine and the wheels to match engine speed to the road speeds and loads encountered. A clutch must be provided so that the engine can be mechanically decoupled from the wheels when the vehicle stops. Additionally, some slippage of the engine with respect to the drive train occurs while starting from a stop. Direct current electric traction motors produce considerable torque at zero RPM and thus may be connected directly to the wheels. Alternating current motors, hydraulic motors and pneumatic motors also produce torque at zero RPM.

Although the term traction motor is usually referred to in the context of a direct current motor, the term is also applicable to alternating current motor applications as well. Additionally, the term traction motor is used to describe any motor of whatever type used to supply torque and power to a vehicle's wheel, tracks, etc.

In small utility vehicles and the like, space is an important consideration in the design of the vehicle. It is therefore desirable to use a small motor, electric, hydraulic, or pneumatic which is capable of supplying required torque and horsepower under all operating conditions. If an electric motor is used it may be an alternating current motor or it may be a direct current motor.

Generally, for a given power, high speed electric motors are smaller in size, lighter in weight, and less expensive than low speed motors. Generally, for a given power, alternating current motors are smaller than direct current motors.

Therefore, it is highly desirable to save space, weight and cost in the powertrain of a utility vehicle through the use of a high speed motor so that the space may be used for batteries, controls or other components.

SUMMARY OF THE INVENTION

As electric motor technology has advanced to provide more performance for less cost it makes sense to replace hydraulic systems with electric systems. Electric motors typically rotate at much higher RPM than hydraulic motors, particularly those suitable for skid-steer loaders. It is desirable to minimize the size of the drive train components so as to maximize the space available for batteries and controls. The vehicle described herein may employ Nickel Metal Hydride, Lithium Ion, Lithium Ion polymer, lead acid batteries or other battery technology.

Although one example of the invention as described herein uses high speed alternating current electric motors it is specifically contemplated that the invention may be used with high speed direct current electric motors, high speed hydraulic motors and high speed pneumatic motors.

The input to the gear box is an offset helical gear driven by a pinion. A planetary sun pinion inputs to the planetary stage. Planetary gear sets provide torque multiplication in compact packages. The output of the gear box is a carrier with a planetary gear-set reduction including a stationary ring gear. The gear box casing includes a ring gear which is a reaction gear and intermeshes with a three-gear planetary set. The carrier of the planetary gear set includes a spline which intermeshes with a splined output shaft.

The offset reduction in the gearbox is an important aspect of the invention as it enables the electric motors to be placed side to side. Use of electric motors is enabled in this application by offsetting the gear box. In this way the left and right side motors can be mounted side-by-side without interference while still maximizing available space for other components such as batteries and controls.

In another example, the offset gear box may be oriented differently (i.e., rotated 180 degrees) with the motors side by side. Although this example may result in reducing the width of the vehicle it may also result in increasing the length of the vehicle. Still alternatively, this example may be used to drive one of the wheel shafts directly.

A wheel driven utility vehicle includes a frame and two high speed alternating current electric motors arranged side by side for driving the vehicle. A variable frequency alternating current drive is utilized to control the speed of the motors and hence to control the direction and turning of the utility vehicle. Instead of high speed alternating current motors, high speed direct current motors, high speed hydraulic motors and/or high speed pneumatic motors may be used.

Each alternating current motor has an output which drives an offset planetary gear reducer. Each offset planetary gear reducer is affixed to the electric motor (or other motor type) and includes an output carrier interconnected with an output shaft. Each output shaft includes first and second chain drive sprockets which drive chains interconnected with shafts driving the front and rear wheels respectively. Each offset planetary gear reducer enables use of space saving high speed relatively low-torque alternating current electric motors (or other motors with similar performance characteristics) with attendant large speed reductions. Gear reduction enables the production of sufficient torque at the wheels of the vehicle. Applications in addition to utility vehicles are also specifically contemplated.

A utility vehicle drive system comprises two alternating current electric motors (or other high speed motors with similar performance characteristics) each having a shaft driven pinion gear. Intermediate gears engage shaft driven pinion gears which in turn drive planetary gears. Each of the planetary gear reducers include an output spline and each of the output splines are axially aligned with each other.

A method for using a high-speed electric motor (or high-speed hydraulic, pneumatic or direct current motors) in a utility vehicle includes the step of orienting the motors having shaft driven pinion gears side by side such that their shaft driven pinion gears are arranged on opposite sides of the vehicle. Next, the offset planetary gear reducers are mounted in engagement with the shaft driven pinion gears. Each of the planetary gear reducers include a gear driven by the shaft driven pinion gear. The gear driven by the shaft driven pinion gears includes a shaft portion formed as a second pinion sun gear which drives a planetary gear set and carrier. The planetary gear set reacts against a ring gear in the casing of the planetary gear reducer. The carrier of the planetary gear reducer includes a splined output. Each of the splined outputs are on the same axis of the other splined output located on the other side of the vehicle. Additionally, the method includes driving an output shaft coupled to the splined output of the carrier of the planetary gear reducer. And, finally, the method includes driving, with chains, the wheel shafts of the vehicle.

It is an object of the present invention to save motor space in a utility vehicle, recreational vehicle, and the like while providing for high torque at the vehicle wheel and tire.

It is an object of the present invention to provide a planetary gear reducer in a utility vehicle, recreational vehicle and the like which enables use of a smaller, lighter, high speed motor while providing for high torque at the vehicle wheel and tire.

It is an object of the present invention to provide a planetary gear reducer in a utility vehicle, recreational vehicle and the like which enables use of a smaller lighter high speed motor selected from the group of alternating current motors, direct current motors, hydraulic motors, and pneumatic motors.

It is an object of the present invention to provide a planetary gear reducer in a utility vehicle, recreational vehicle and the like which enables use of a smaller, lighter, high speed alternating current electric motor while providing for high torque at the vehicle wheel and tire.

It is an object of the present invention to provide for an efficient planetary gear reducer for use in a utility vehicle, recreational vehicle and the like.

It is an object of the present invention to provide for two offset electric motors in a utility vehicle, recreational vehicle, and the like by utilizing two offset planetary gear reducers.

It is an object of the present invention to utilize high speed alternating current motors in a utility vehicle, recreational vehicle or the like.

It is an object of the present invention to provide a method of using two high speed electric motors.

It is an object of the present invention to provide offset planetary gear reducers for use in combination with high speed motors for efficient use of space in a utility vehicle.

It is an object of the present invention to provide offset planetary gear reducers for use in combination with alternating current electric motors for efficient production of torque at the wheels of a utility vehicle.

These and other objects of the invention will best be understood when reference is made to the Brief Description of the Drawings, Description of the Invention and Claims which follow hereinbelow.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a plan view of a prior art Skid-Steer vehicle powered by two DC traction motors.

FIG. 2 is a top plan view of the utility vehicle illustrating two alternating current motors oriented side by side with each having an offset planetary gear reducer driving a respective output shaft.

FIG. 2A is an enlarged portion of FIG. 2 illustrating a portion of the left side of the vehicle.

FIG. 2B is an enlarged portion of FIG. 2A illustrating the gear reducer and output shaft.

FIG. 2C is an exploded view of the input to the gear reducer, the gear reducer, and the output shaft.

FIG. 2D is a perspective view of the carrier and the output shaft.

FIG. 2E is a perspective view of the offset planetary gear speed reducer.

FIG. 3 is a block diagram of the method for using high speed alternating current electric motors with offset planetary gear reducers.

The drawings will be best understood when reference is made to the Description of the Invention and Claims below.

DESCRIPTION OF THE INVENTION

FIG. 2 is a top plan view 200 of the utility vehicle illustrating two alternating current electric motors 201, 202 oriented side by side with each having an offset planetary gear reducer 203, 204 driving a respective output shaft 208, 214. Although reference numerals 201, 202 refer to high speed alternating current electric motors, it is specifically contemplated that other high speed motor types may be used such as direct current motors, hydraulic motors and pneumatic motors.

The utility vehicle includes a frame 205, 206, 250, 251 for supporting vehicle components. As illustrated in FIG. 2, side frame member 205 is on the left hand side of the vehicle and side frame member 206 is on the right hand side of the utility vehicle. The two side frame members 205, 206 are shown in section in FIG. 2, FIG. 2A, and FIG. 2B.

Frame side member 205 supports first chain driven wheel shaft 210. Sprocket 210S is formed as part of the wheel shaft 210 or alternatively is a separate sprocket affixed or attached to the wheel shaft 210. Frame side member 205 also supports the output shaft 208 of the planetary gear reducer 203.

Output shaft 208 includes two sprockets 208S which are identical. The sprockets 208S may be an integral part of shaft 208 or they may be separately attached to the shaft. A metal chain 210 interengages sprockets 210S and 208S and communicates horsepower and torque therebetween. The reduction ratio of output shaft driving sprocket 208S to driven sprocket 210S is approximately 2.5-5:1 such that for every rotation of the output shaft 208 the forward sprocket 210S and wheel shaft 210 turns 0.4 to 0.2 of a turn or revolution. Reduction in speed of the driven sprocket 210S results in a corresponding increase in torque for a given applied power.

Referring to FIGS. 2 and 2B, output shaft 208 is splined and is coupled to the splined output 230T of the carrier 230 of the planetary gear reducer 203. Frame side member 205 also supports the second chain driven wheel shaft 212. Sprocket 212S is formed as part of the wheel shaft 212 or alternatively is a separate sprocket affixed or attached to the wheel shaft 212 for driving a rearward wheel 212A.

Metal chain 211 interengages sprockets 212S and 208S and communicates horsepower and torque therebetween. The reduction ratio of the output shaft driving sprocket 208S to driven sprocket 212S is approximately 2.5-5:1 such that for every rotation of the output shaft 208 the rearward sprocket 212S and wheel shaft 212 rotates just 0.4 to 0.2 of a turn or revolution. The reduction in speed of the driven sprocket 212S results in a corresponding increase in torque for a given applied power.

Similarly, the structure and operation of driven sprockets 216S, 217S, shafts 216, 217, frontward and rearward wheels 216A, 217A, sprockets 214S, shaft 214 and chains 213, 215 on the right side and within the right frame 206 are identical to the left frame side member 205 and frame 205. The reduction ratio of the output shaft driving sprocket 214S to driven sprockets 216S, 217S is the same as in connection with the left side of the vehicle, namely, approximately 2.5-5:1.

Speed reduction of approximately 2.5-5:1 just described are in addition to the speed reduction of the planetary gear reducers 203, 204 which are described further herein. Alternating current motors 201, 202 reside side by side and have output shafts 221S, 222S with pinion gears 221, 222 thereon for driving two offset planetary gear reducers 203, 204 to effect speed reduction and increase torque. Alternatively, a helical pinion gear 221 H and a helical driven gear 223 H. Full load electric motor torque is generally defined as follows:

Torque(ft-lbs.)=5250×horsepower/RPM

Generally, for a given power, high speed electric motors are smaller in size, lighter in weight, and less expensive than low speed motors. Generally, for a given power, alternating current motors are smaller than direct current motors. Additionally, for a given power, alternating current motors are smaller than direct current motors.

Use of planetary gear reducers 203, 204 with alternating current motors 201, 202 saves space. As previously stated the motors may be hydraulic, pneumatic or direct current motors. Reducers 203, 204 are approximately 8 inches in diameter and approximately 5.5 inches deep and occupy a volume of approximately 300 cubic inches.

FIG. 2A is an enlarged portion 200A of FIG. 2 illustrating a portion of the left side of the vehicle and FIG. 2B is a further enlargement of a portion 200B of FIG. 2A illustrating the gear reducer 203 and pinion 221 on output shaft 221 S in more detail.

Referring to FIGS. 2A and 2B, the alternating current motors 201, 202 are controlled by a variable frequency drive (not shown) to control the speed of the motors. Preferably the alternating current motors are three phase motors. Each of the offset planetary gear reducers 203, 204 include a housing having a ring gear 224 affixed thereto. Ring gear 224 is trapped between housing portions 203, 203A of the reducer. Seals 224S prevent leakage of lubricant from within the gear casing.

Each of the planetary gear reducers 203, 204 includes a carrier 230 having planetary gears 225, 226, 229 intermeshing with the ring gear 224 and an output spline 230T. Although the planetary gear reducer illustrated has three planetary gears, any reasonable number of planetary gears may be used. Each of the planetary gear reducers includes a gear 223 having teeth 223T driven by the pinion gear 221 of the output shaft 221 of the alternating current motor 201. The gear 223 driven by the pinion gear 221 of the output shaft 221S of the alternating current motor 201 includes a shaft portion forming a sun pinion 227 with gear teeth 227T.

Sun pinion or gear 227 intermeshes with three planet gears 225, 226, and 229 each of which naturally include teeth 225T, 226T and 229T which intermesh with ring gear 224. Ring gear 224 extends around the inner circumference of the gearbox. Each of the chain drive shafts 208, 214 includes a spline 208T thereon which intermeshes with output spline 230T of the carrier 230 as best viewed in FIG. 2B. Planetary gear reducers 203, 204 effect a speed reduction in the approximate range of between 20-30:1. That is for every revolution of the input pinion gears 221, 222, the carrier 230 will rotate 1/20 to 1/30 of a revolution. Other speed reductions are specifically contemplated. Chain drive sprockets 208S, 214S in combination with wheel shaft sprockets 210S, 212S, 216S and 217S effect a speed reduction in the approximate range of 2.5-5:1. That is, for every one rotation of the chain drive sprocket 208S, the wheel sprockets 210S, 212S will rotate 0.4 to 0.2 of a revolution. Other speed reductions are specifically contemplated. Since torque is inversely proportional to the shaft rotational speed, torque is increased with a reduction in speed.

Other speed reductions are specifically contemplated depending on the desired torque at the wheels and traveling speed of the machine taking loads, inclines and other variables into consideration. Use of the offset speed reducer as disclosed herein enables the efficient use of space and provides the same torque to the wheel with less input torque supplied by the high speed electric motor. The efficiency of the offset speed reducer is approximately 95% at rated load.

Use of the offset speed reducer and electric motors enables use of high speed, light weight electric motors which are smaller in diameter and output less torque than slower, heavier larger motors whether they are alternating current motors or direct current motors. The savings in space, weight and money attained by use of the offset planetary gear reducers with high speed motors is considerable. Use of planetary gear reducers provides a stable transmission of power with torque amplification inversely proportional to the speed reduction. The planetary gear reducers of the instant invention weigh approximately 100 pounds but can vary in weight depending on the materials used such as steel, stainless steel or aluminum. The gears 223, 225, 226, 229 and the carrier 230 are made of steel or stainless steel. Aluminum may be used for the gearbox casing 203, 203A if extremely light weight is desired. The low weight of the gear reducer having a volume of about 300 cubic inches (approx. 8 inches in diameter and 5.5 inches deep) in combination with a light-weight alternating current motor provides a compact low cost arrangement when placed side by side as illustrated in FIG. 2.

Alternating current electric motors 203, 204 are water cooled motors and run at 7,000 to 8,000 RPM. At approximately 7500 RPM the three phase electric motor outputs approximately 14.75 ft-lbs. of torque which equates to approximately 21 horsepower. The peak starting torque is about 77 ft-lbs. The motors to be used are about 14 inches long and 8 inches in diameter and have a volume of approximately 700 cubic inches.

FIG. 2C is an exploded view 200C of the input to the gear reducer 221T, the gear reducer 203, and the output shaft 208. Referring to FIGS. 2B and 2C, sun pinion 227 is supported by bearing 223B and 227B. Use of gear 223 enables the planetary gear reducer to be offset as it is driven by pinion 221 which is on the shaft 221 S of the electric motor. Three planet gears 225, 226 and 229 and, more specifically, their teeth 225T, 226T and 229T intermesh with sun pinion teeth 227T and ring gear 234 and its teeth 234T.

Planet gears 225, 226 and 229 are supported by bearings (i.e., 235B) and are pinned to the carrier by pins. See, for example, pin 235 in FIGS. 2A and 2B. Pin 225 P restrains pin 235 from movement within the carrier 230 and thus secures gear 225 in place. Gear 225 and the other planet gears are, of course, free to rotate but they are securely fastened to the carrier and impart rotational motion to the carrier 230. Reference numeral 225A indicates intermeshing between planet gear teeth 225T and ring gear teeth 224T. Referring to FIG. 2A, output shaft 208 is supported by bearings 208B and 208C and intermeshes its spline 208T with spline 230T of the carrier.

Planetary gear reducer 203 distributes the load evenly to three planets, 225, 226 and 229. As previously indicated any reasonable number of planet gears from 1 to “n” may be used. Reciting the operation of the gear reducer, torque is applied by shaft 221S through teeth 221T of pinion 221 which imparts rotational movement and torque to gear 223. Gear 223 includes sun pinion 227 which by and through its teeth 227T imparts rotational movement and torque to gears 225, 226 and 229 via teeth 225T, 226T and 229T. As previously stated planet gears 225, 226 and 229 are free to rotate and impart rotational movement to carrier 230 effecting a speed reduction which is transmitted to output shaft 208 which is interconnected with the carrier spline 230T. The gearbox 203, 203A is separable into two portions 203 and 203A and they trap ring gear 224 when the gearbox is secured by fastener 240A to the electric motor 201 and when the portions 203, 203A are secured together by fastener 240.

FIG. 2D is a perspective view 200D of the carrier 203, 203A, planet gears 229 and 225, and output shaft 208 with a corresponding spline 208T. FIG. 2E is a perspective view 200E of the offset planetary gear reducer without bearing 208B illustrated therein. The principal dimensions of the offset planetary gear reducer are approximately 8 inches in diameter and 5.5 inches deep neglecting the input housing 241 which houses pinion 221. The offset planetary gear reducer is generally cylindrically shaped and includes a housing 241 for the shaft driven pinion gear 221. A flange (unnumbered) is fastened to the motor 201.

FIG. 3 is a block diagram 300 illustrating a method for using high-speed electric motors in combination with offset planetary gear reducers in a utility vehicle. The first step includes orienting two high speed electric motors having shaft driven pinion gears side by side 301 such that their shaft driven pinion gears are arranged on opposite sides of the vehicle. Next, the method includes mounting offset planetary gear reducers in engagement with the shaft driven pinion gears 302. Each of the planetary gear reducers 203, 204 include a gear driven by the shaft driven pinion gears 221, 222. The gear driven by the shaft driven pinion gears includes a shaft portion formed as a sun pinion gear 227 which drives a planetary gear set and carrier 230 reacting against a ring gear 224 in the casing of the planetary gear reducer 203, 203A. The carrier 230 of the planetary gear reducer includes a splined output 230T and each of the splined outputs 230T are on the same axis. The method further includes driving an output shaft 208, 214 coupled to the splined output 230T of the planetary gear reducer. Finally, the method includes driving, with chains (209, 211, 213, 215), the wheel shafts (210, 212, 216, 217) of the vehicle.

A list of reference numerals follows.

REFERENCE NUMERALS

-   14 a-d-tires of vehicle -   28-battery -   60, 64-motor -   62, 66-sides of vehicle -   68, 84-coupling -   70, 82-spur gear reduction assembly -   72, 86-chain -   74, 76, 88, 90-gears -   78, 80, 92, 94-axles -   70, 82-spur gear reduction assembly -   100-prior art utility vehicle -   200-utility vehicle -   200A-enlarged portion of utility vehicle -   200B-further enlargement of planetary gear reducer -   200C-exploded view of powertrain -   200D-perspective exploded view of carrier and output shaft -   200E-perspective view of offset planetary gear reducer -   201, 202-alternating current motor -   203, 203A, 204-gearbox -   205, 206-vehicle side wall -   208, 214-output shafts -   208B, 223B, 227B, 235B, 208C-bearing -   208T-spline on output shaft -   209, 211, 213, 215-drive chains -   210, 212, 216, 217-wheel shaft -   210A, 212A, 216A, 217A-wheel tire -   221T-pinion teeth -   221, 222-motor shaft pinion gear -   221H-helical pinion -   221S, 222S-motor shaft -   223-gear -   223H-helical gear -   223B-bearing -   223T-teeth on gear -   224-stationary ring gear -   224T-ring gear teeth -   224S, 259S-seal -   225, 226, 229 -planet gear -   225A-mesh between planet gear teeth 223T and ring gear teeth 224T -   225P-pin -   225T, 226T, 229T-planet gear teeth -   227-sun pinion -   227T-sun gear teeth -   230-carrier -   230T-spline on carrier -   235-pin -   240, 240A-bolt -   241-pinion housing -   250, 251-frame member -   300-block diagram of method of using high speed motor and offset     planetary gear reducers -   301-orienting and mounting high speed motors side by side with     pinions oppositely arranged -   302-mounting offset planetary gear reducer in engagement with the     shaft driven pinion gears 303-coupling an output shaft to the spined     output at a desired rate -   304-driving the wheel shifts of the vehicle

The invention has been set forth by way of example with particularity. Those skilled in the art will readily recognize that changes may be made to the invention without departing from the spirit and the scope of the claimed invention. 

1. A wheel driven utility vehicle comprising: a frame; a high speed motor having an output shaft with a gear thereon; an offset planetary gear reducer driven by said output shaft of said gear of said high speed motor and affixed thereto; said offset planetary gear reducer includes an output carrier interconnected with an output shaft; said output shaft includes first and second chain drive sprockets; forward and rearward wheel shafts each having a wheel sprocket; a first and second chain; said first chain interengaging said first chain drive sprocket and said forward wheel sprocket driving said forward wheel shaft; and, said second chain interengaging said second chain drive sprocket and said rearward wheel sprocket driving said rearward wheel shaft.
 2. A wheel driven utility vehicle as claimed in claim 1 wherein said motor is an alternating current motor controlled by a variable frequency alternating current drive.
 3. A wheel driven utility vehicle as claimed in claim 1 wherein said planetary gear reducer is in the range of 20:1 to 30:1.
 4. A wheel driven utility vehicle as claimed in claim 2 wherein said alternating current electric motor operates at full load between 7-8,000 rpm outputting approximately 14.75 ft-lbs. of torque.
 5. A wheel driven utility vehicle as claimed in claim 1 wherein the forward and rearward wheel sprockets are larger diameter than the first and second chain drive sprockets of the output shaft effecting a gear reduction in the range of approximately 2.5 to 5:1.
 6. A wheel driven utility vehicle as claimed in claim 4 wherein said first and second drive sprockets and said first and second wheel sprockets each have a reduction in the range of 2.5 to 5:1.
 7. A utility vehicle comprising: a frame having two sides thereof; two motors oriented side by side, each of said motors includes an output shaft; two offset planetary gear reducers driven by said output shafts of said motors and affixed thereto; said offset planetary gear reducers include output carriers interconnected with output shafts; said output shafts each include first and second chain drive sprockets; each side of said frame includes forward and rearward wheel shafts each having wheel sprockets; each side of said frame includes first and second chains; said first chains each interengaging said first chain drive sprockets and said forward wheel sprockets driving said forward wheel shafts; and, said second chains each interengaging said second chain drive sprockets and said rearward wheel sprockets driving said rearward wheel shafts.
 8. A utility vehicle comprising a frame; said frame includes two sides thereof each supporting a first chain driven wheel shaft having a sprocket for driving a forward wheel and a second chain driven wheel shaft having a sprocket for driving a rearward wheel; each side of said frames includes a chain drive shaft having two sprockets thereon for driving first and second chains, said first chain intermeshing with one of said sprockets of said wheel drive shaft and said sprocket for driving a forward wheel and said second chain intermeshing with the other sprocket of said wheel drive shaft and said sprocket for driving a rearward wheel; two alternating current motors residing side by side, each of said alternating motors having an output shaft for driving an offset planetary gear reducers to effect speed reduction and increase torque; said alternating current motors controlled by a variable frequency drive to control the speed of said motors; said output shaft of each of said alternating current motors having a pinion gear thereon; each of said offset planetary gear reducers includes a housing having a ring gear affixed thereto; each of said planetary gear reducers includes a carrier having at least one planetary gear intermeshing with said ring gear and an output spline; each of said planetary gear reducers includes a gear driven by said pinion gear of said output shaft of said alternating current motor, said gear driven by said pinion gear of said output shaft of said alternating current motor includes a portion having a sun gear thereon which intermeshes and drives said at least one planet gear of said carrier; each of said chain drive shafts includes a spline thereon and intermeshes with said output spline of said carrier; said planetary gear reducers effecting a speed reduction in the approximate range of between 20-30:1; and, said chain drive sprockets in combination with said wheel shaft sprockets effecting a speed reduction in the approximate range of 2.5-5:1.
 9. A utility vehicle drive system comprising: two alternating current electric motors each having a shaft driven pinion gear; intermediate gears in engagement with said shaft driven pinion gears, said intermediate gears driving said planetary gears, each of said planetary gear reducers include an output spline and each of said output splines are axially aligned with each other.
 10. A utility vehicle drive system as claimed in claim 9 wherein said electric motor is a three phase motor.
 11. A wheel driven utility vehicle as claimed in claim 9 wherein said alternating current electric motor operates at full load between 7-8,000 rpm outputting approximately 14.75 ft-lbs. of torque.
 12. A wheel driven utility vehicle as claimed in claim 9 wherein said alternating current electric motor has an approximate volume of 700 cubic inches.
 13. A utility vehicle drive system as claimed in claim 2 wherein said electric motor is a three phase motor.
 14. A wheel driven utility vehicle as claimed in claim 2 wherein said alternating current electric motor has an approximate volume of 700 cubic inches.
 15. A method for using a high-speed motor in a utility vehicle, comprising the steps of: orienting two high speed motors having shaft driven pinion gears side by side such that their shaft driven pinion gears are arranged on opposite sides of the utility vehicle; mounting offset planetary gear reducers in engagement with said shaft driven pinion gears, each of said planetary gear reducers include a gear driven by said shaft driven pinion gears, said gear driven by said shaft driven pinion gears includes a shaft portion formed as a second pinion gear which drives a planetary gear set and carrier reacting against a ring gear in the casing of the planetary gear reducer, said carrier of said planetary gear reducer includes a splined output, and each of said splined outputs being on the same axis of each other; coupling an output shaft to said splined output of said planetary gear reducer and driving said output shaft at a desired rate; and, driving, with chains, said wheel shafts of said vehicle.
 16. A method for using a high-speed motor in a utility vehicle as claimed in claim 15 wherein the high speed motor is an electric motor and further comprising the steps of controlling the speed of the electric motors.
 17. A method for using a high-speed motor in a utility vehicle as claimed in claim 15 wherein the high-speed motor is a hydraulic motor.
 18. A method for using a high-speed motor in a utility vehicle as claimed in claim 15 wherein the high-speed motor is a pneumatic motor.
 19. A method for using a high-speed motor in a utility vehicle as claimed in claim 15 wherein the high-speed motor is a direct current motor.
 20. A wheel driven utility vehicle as claimed in claim 1 wherein said high-speed motor is a hydraulic motor.
 21. A wheel driven utility vehicle as claimed in claim 1 wherein said high-speed motor is a pneumatic motor.
 22. A wheel driven utility vehicle as claimed in claim 1 wherein said high-speed motor is a direct current motor. 